Patented Dec. 24, 1929

1,740,737

UNITED STATES PATENT OFFICE

DAVID FORBES KEITH, OF TORONTO, ONTARIO, CANADA

REFRIGERATING DEVICE

Application filed. June 27, 1927. Serial No. 201,904.

My invention relates to refrigerating de vices operating upon the
absorption system, and, more particularly to units which are
separable from the refrigerator boxes or other coolers in which they
are intended to be employed.

While my device is a departure in some of its principles of
operation from standard ab sorption systems, in that there are no
check valves employed by me, it operates through a similar cycle to
all intermittent absorption systems, that is to say, I provide two
receptacles, one a generator-absorber, which contains a suitable
liquid, such as water, and the other an evaporator-condenser, which
contains a suitable refrigerant, such as ammonia, with suitable
connecting paths between the two receptacles so that when the
generator-absorber is heated, the gases will pass over into the
evaporator-condenser receptacle, by one path, and when the
generator-absorber is permitted to become cool, it will reabsorb the
gases, as they volatilize in the evaporator -condenser receptacle,
said gases pass back and are absorbed in the liquid in the
generator-absorber, with the result of absorption of heat (production
of cold), within and about the evaporator-condenser receptacle.

As intimated above, one of my objects is to provide a
refrigerating unit of light weight. Another object is to provide
means in connection with a novel arrangement which guides the user in
locating the unit during the generation period, the refrigerating
period and in draining back the water of condensation into the
generator-absorber, for the retention of sufficient liquid to serve
the function of a seal when the device is in operation. Other objects
are to provide a system of ab sorption which operates efficiently
without the use of mechanical valves, to provide a method of
dehydrating and cooling the gas passing from the generator, and to
provide an efficient method of increasing the rate of heat exchange
between the generator-absorber and its surroundings. It is also my
object to provide a simple and effective method of attaching metal
fins to the generator shell.

A general object of my invention is to provide a structure which
will be simple to make, and foolproof in operation, and which can be
readily moved about during the respective periods of generation and
absorption, so that the generator-absorber can be placed over a
flame, during generation, and the evaporator-condenser receptacle be
placed into a water vessel during condensation and a suitable box,
vessel or receptacle during evaporation and absorption, with the
generator-absorber on the outside of the said box, in the last
instance.

In this connection, it is my object to make the two main
receptacles of spherical shape and light in weight and to connect
them by means of tubular means which will serve as a support for the
device when in use, and to which a handle for moving it about may be
applied.

It is my object to provide for an automatic warning which will
indicate by sound or change in color, when the operation of
generation has been completed.

It is my object to provide in connection with the
evaporator-condenser element for a simple mode of freezing desired
materials in a "tray."

It is my object to provide in connection with my device for a
simple means of assuring a proper cooling action in the
evaporator-condenser element during condensation, preferably by means
of a suitable circulation de vice in the nature of e dome which sets
up cooling currents of water about the evaporator-condenser shell,
and a circulation throughout the entire water vessel.

The above and various other advantages. I provide by that certain
construction and arrangement of parts, of which a typical ex ample
will be hereinafter more specifically pointed out and described, and
the novelty of which will beset forth in the appended claims.

In the drawings:&emdash;

Figure 1 is a central longitudinal
section taken through the selected example to be de scribed,
showing my invention.

Figure 7 is a section showing the device
in the act of generation and condensation.

Referring first to the evaporator-condenser, it is illustrated as
a hollow spherical shell 1 having an outlet tube 2 which lets into
the tube 3. The tube 3 is connected to a tube portion 4 which is bent
around at each end, and is connected to the generator-absorber. The
tube portion 4 is generally of U shape, as noted, but has a
considerable portion of its length in what might be termed the base
of the U shape. This tube portion 4 is to be used as a hanger for the
device. It is also equipped with a handle 5 by means of which the
device is manipulated, which handle is placed so that the two parts
of the structure are substantially balanced at the point where the
handle will be grasped. The shell has a chamber 1a formed therein,
same opening to the outside. Into this chamber an ice tray may be
inserted.

The lower portion of the tube 3 is closed by a base plate 3a and
may be surrounded by an insulating shell in tubular form, as
indicated at 3b. This portion of the tube serves as a sump for
condensed absorbent or over flow.

The generator-absorber is formed of a spherical shell portion 7,
having heat exchange fins arranged about its surface, in vertical
planes. These fins are a novel conception, and are formed of pieces
of sheet metal 8, bent to form flanged channels, of which the flanges
are soldered or otherwise attached to the shell.

The function of the fins is to exchange heat with their
environment by both radiation and convection, more particularly the
latter, be cause they form passages or flues for movement of air or
other cooling fluid, up along the shell, within the channels. The
passage of the air greatly, increases the cooling effect, and the
section strengthens the. fins and re duces the cost. I find that the
channel-like fins are a very decided advantage over the usual type of
fin.

Mounted over the top of the generator-absorber shell is a device
having a dome shaped body 9 which is soldered or otherwise attached
to the shell 7. The device has a base plate 10, which is formed up
centrally at 11 about the tubular end 7a of the shell 7 some what
similarly to a cake pan. The central portion 11 is secured at its
upper end to the dome by crimping to form a substantially steam tight
joint. The part 10 is spaced slightly from the dome, and a tube 12 is
soldered to the top of the portion 9, and ex tends through the plate
10, communicating direct with the shell 7. A tube 12a extends from
the tube 12 to the interior of the dome.

Water is placed into the interior of the dome through a small hole
13, and a whistle 14a is set into the dome to be operated from steam
escaping through the whistle tube ex tending through the closed end
of the tube 12. The water in the dome aids materially in dehydration
or pre-cooling of the gas from the generator.

The result of the structure is that the water in the dome, when
the generator-absorber is being heated, will rise in temperature,
commence to boil, and at a predetermined stage in the generation
period, the rate of formation of steam, balanced against the rate of
passage of steam through the gauged opening 13, will cause a steam
pressure sufficient to lift the water to a point where some of it
will flow up through the tube 12a, so that it falls through the tube
12 against the shell 7. This water, on reaching the hot generator
shell 7, is flashed into steam which causes the whistle 14a to blow,
and stops the water coming up from the dome 9. When the first portion
of water has all been evaporated, the whistle ceases to blow until
the pressure has once more been sufficiently built up to send down
another portion of water. In this way a repeated action of the
whistle is secured.

The operator will be able to apply heat to the generator-absorber,
and need do nothing more until the whistle begins to blow, after
which he will wait such time as is required, which will be only a few
minutes, before he takes the generator-absorber away from the heat.
Some other signal of thermostatic, thermoplastic, or phosphorescent
may be used instead of the one indicated.

The generation and absorption passages between the two receptacles
are formed in the illustrated embodiment as follows:

The tubular upper end 7a of the shell 7 is closed at the entrance
to the shell? by a partition or plate 15. The plate 15 has a hole for
passage of the absorption pipe 16, which ex tends down to a point
below the level of ab sorbent in the shell 7. It is quite important
to have the lower end of the pipe 16 open and to terminate near the
surface of liquid in the shell 7 when the absorption begins to take
place. This level is indicated by the line B in Fig.
1. For circulation, the tube lob may be set into the shell so as
to surround the end of the tube 16, but not impede the efflux of gas
from the mouth of the tube 16.

The closed lower end of the portion 7a forms in this portion of
the system, a liquid seal, and the tube 16 defines the level of ab
sorbent, be it water or whatever agent is used, so that normally the
inflow into the shell 7 is through the tube 16, but the outflow
passes through another set of passages, and bubbles up through the
liquid seal.

To provide this structure I find a simple mechanism to be as
follows:&emdash; A tube 17 extends from an opening through the plate
15, which permits generated gases to pass out of the shell 7 into a
closed vessel or "can" 18. From this can a tube 19 extends down to a
point near the plate 15, thus bringing the end of the tube 19 to the
bottom of the liquid seal.

Located in the upper end of the tube portion, 3 is a vessel 20,
smaller than the tube 3, and closed at the bottom. The vessel is
secured in the tube 3 by means of spaced lips 20, so that there is a
passage for generated gases around the outside of the vessel. The
outlet tube 2 from the shell 1 is closed at the end, and has a series
of holes 2a in its lower face. These holes provide the passage to and
from the shell 1.

The sump lies below the end of the tube 2, and the vessel 20 is
normally filled with the mixture of absorbent and refrigerant,
usually water, and ammonia as stated. The hot gases passing down
around vessel 20 are cooled by vaporizing the refrigerant from the
mixture in the vessel 20 and also by the contact with the tube 3
which is submerged in water.

The shell 1 has a dome erected thereon in the shape of a spaced
half spherical dome 21, having a neck and mouth 21, and held in place
by means of spaced strips 21b.

I have not described or shown in detail drain openings, and
pressure relief valves, except, that I have indicated at 23, a
suitable pressure relief device, and at 22 a suitable charging
opening and plug.

When the device is employed in a refrigerator box or cabinet,
which is the typical use of the device, I provide a suitable box 26,
having a lid 26a hinged thereto, or otherwise removably set thereon,
and leaving sufficient space at least for the insertion of the shell
1. The side wall of the box has a groove 27 therein which will fit
the tube 4, and channeled to seat the bracket 32, or the lid and
groove can be formed to cooperate in enclosing the box about the tube
4. The shell 1 is placed in the box, and the lid closed clown leaving
the shell 7 outside. Inside of the box a strap or loop 28 is secured
on the lower inside of the box in such a position that the lower end
of the tube 3 can be thrust there in, thus resisting the rocking
tendency of the weight of the shell 7 and holding the device against
tipping.

As a water cooling means used in the cycle of operations as will
be described, I normally provide a water vessel or tub 30. This tub
has a bracket 31 on the outside. I locate on the underside of the
tube 4, so as to be near the point where the tube bends clown to the
tube 3, a bracket 32, in the form of a plate soldered in place, and
presenting two shoulders 32a and 32b.

When the generator shell is being heated, the shell 1 is set into
the tub of water, leaving the bracket 32 inside of the tub at its
rim. The shell 7, which is full of absorbent and refrigerant at the
beginning of this operation, rests against the bracket 31, and the
nature of the support is such that the weight of the shell 7 and its
content acts to overcome the buoyancy of and to submerge shell 1.

For defining a draining position for the device, in the cycle of
operations which will be described, I locate at the end of the handle
5 a foot 25, which can be rested on the door or a table or other
supporting surface, and the location of the device in an inverted
position supported by the foot and the shell 7, as shown in Figure
6 is thus defined.

As described, the device will be considered as filled with
absorbent, usually water, together with dissolved refrigerant, for
example ammonia, so that the shell 7 is filled to a level such as
that noted at 34, the lower portion of 7a is filled to the level
noted at 35, and the vessel 20 to the level noted at 36. The water
dome, where this form of signal is employed, will be considered as
having water therein. At the start of the operation the level 34 is
correct, but when the refrigerant fully generated, the level is at B.

The shell 1 is set into a tub of water as preferably indicated in
Figure 7, in which case the mouth of the dome
neck is located below the level of water in the tub. The shell 7 is
placed over a heater 3B.

The application of heat causes the refrigerant gases to pass up
through the tube 17 into the small container 18, which is closed
except for the tube 19. The container or vessel 18 acts to prevent
the sudden movement of gas under pressure, from forcing the liquid in
the seal in the portion 7a to rise suddenly through the tube 19, thus
destroying the seal. The part 18 acts as a trap and its equivalent
would be an enlargement located in the connection between the tubes
17 and 19. The part 18 also assists in maintaining the level of
liquid in the seal.

The effect of the water in the dome around the portion 7a of the
structure tends to impart a preliminary cooling. The refrigerant
under pressure passing through the tube 17 and compartment 18, and
down through the tube 19 bubbles up through the liquid absorbent in
the portion 7a, and thence passes into the tube portion 4. A small
proportion of the absorbent is usually gasified along with the
refrigerant.

Condensation of the absorbent in the compartment 13 and the tube
19 results in a supply of liquid being kept up in the seal at 7a.

The gas passes from the tube 4 into the tube 3, where it must
follow the passage around the outside of the vessel 20. Here the
refrigerant gives up heat in two ways: (1) to the water in the tub,
in which a portion of the tube 3 is plunged at the time, and (2) to
the vaporizing of such refrigerant as is contained in the mixture in
the vessel 20. This act of vaporizing the refrigerant absorbs
considerable heat, and also returns the refrigerant to the system.

This cooling causes the absorbent to con dense in the form of a
mist contained in the still gasified refrigerant, which mist will be
deposited upon surfaces with which it must contact. Some collects on
the inside of the tube 3 and the outside of the vessel 20. The gases
must pass down around the tube 2 and up through the holes 2a. In
doing so, practically all of the mist is deposited and runs down into
the sump in the lower end of the tube 3.

The refrigerant fairly clear of absorbent medium by this time
passes into the cold ball 1, where it is condensed to a liquid, as a
result of its heat being given up to the walls of the cold ball, and
thence to the water in the tub.

The condensation of the refrigerant starts to take place when the
pressure resulting from the heating of the shell 7 builds up a
sufficient heat within the shell 1 or cold shell.

The heating of the shell 7 is continued until the maximum desired
amount of refrigerant in the system has been boiled out of the
absorbent. At this period the warning whistle will begin to operate,
and after it has operated for several periodic intervals, the hot
shell is taken away from the heater, and the heat turned off. It
should be noted that the liquid in the shell 1 Figure
1 at 1b is not present when the shell 7 is filled to the level
shown. The shell 1 is normally empty when the shell 7 is full.

Proceeding with the operation, the hot shell may then be cooled in
the water tub for a short interval.

The action of the shell 1 or cold shell is much enhanced by the
circulation dome 21. The mouth of the dome is held below the level of
the cooling water in the tub by reason of the fact that the whole
weight of the device is applied to holding it down. Thus the bracket
shoulder 32a provides a rib for hooking the tube portion 4 over the
wall of the tub. The bracket 31 holds the hot shell away from the tub
and prevents the device from tipping, so that the whole system weighs
down the cold shell, and keeps it in the position indicated in
Figure 7. The water flows up around the dome
and out through the mouth thereof, causing a circulation through the
whole tub. If the safety device in the cold shell should rupture, the
refrigerant will be absorbed or dissolved in the water of the tub.

In placing the hot shell in the tub, the shoulder 32b of the tube
bracket is hooked over the edge of the tub, and the shell 1 abuts the
bracket, or rather the lower end of the tube 3 abuts it, resulting in
keeping the hot shell down, and incidentally in resupplying water in
the steam dome on the hot shell, through the hole 13 therein.

The device is then placed into the refrigerator box, as explained,
and the hot ball being partially cooled, and this cooling being much
enhanced by the fins, as described, will continue to become lower in
temperature. This lowers the pressure in the system, causes the
refrigerant to slowly evaporate in the cold ball, and to pass back
from the cold shell in the same way that it entered it. The gases
pass down through the tube 16, since they cannot pass through the
liquid seal, and set up an agitation as they bubble into the
absorbent the hot shell. This action results in the great reduction
of temperature of the shell 1 and the tube 3. The absorbent is
strongly avid for the refrigerant, and absorbs it as fast as it
enters through the tube 16. this action being greatly enhanced by the
bubbling and agitation of the absorbent by the influx of the gas. The
bubbling and agitation results from the end of the tube 16 being near
the surface of the liquid in the shell 7 and also from the end of the
tube being open.

When the refrigerant medium has sufficiently passed back to the
hot shell again, it is necessary before reheating to drain the
system. This is so because what residue of the absorbent is left in
the cold shell and the sump should be returned.

The device is set into the position as guided by the shoe on the
handle, as described, and as shown in Figure 6,
which establishes a level of liquid in the system, about as shown in
the dotted line A of Figure 1. The drainage
having taken place, the device is righted again, which results in all
of the liquid in the system flowing into the shell 7 except
sufficient to fill the vessel 20, and the liquid seal in the portion
7a. Any excess will pass into the sump, but it will be difficult to
even completely fill the vessel 20, upon righting the device, due to
the proportions and shapes of the elements thereof.

Since there are no losses in the system, it will continue to
function in the cycle noted, with intervals of absorption, drainage
and generation.

I have not illustrated the seams formed in making up the two
shells, and uniting the tubular portions and shell together, as this
may be accomplished in any desired way.

Its inexpensiveness and easy operation, makes my device available
for domestic refrigeration at a cost which is very much lower than
present systems, and brings artificial refrigeration within the
economical resources of those of moderate means.

It will be evident that modifications of the structural details of
my device may readily be made without departing from the invention
therein, and I do not wish to represent that the embodiment of my
invention selected for purposes of illustration, is the only way in
which my invention can be brought to practical use.

Having thus described my invention, what I claim as new and desire
to secure by Letters Patent, is -

1. In combination, a refrigerator box, and a removable
refrigerating unit therefor, said box having an opening therein, a
groove in the upper edge of the wall about said opening, said unit
having its portions connected together solely by means containing
the passageways between the portions, said means arranged to fit
in said groove, for the purpose described.

2. In a portable refrigerating unit, the combination of a
generator-absorber, a condenser-evaporator, and passageways
between them, to provide separate paths for flow of gases in
opposing directions, said passageways including a liquid seal
composed mainly of the liquid absorbent used, means for defining a
refraining position for said unit, and means for retaining liquid
for return to the seal upon righting the unit from refraining
position.

3. In a refrigerating device, a generator-absorber, connections
therefrom through two passages, a liquid seal composed mainly of
the liquid absorbent used above which one of the passages
terminates, and within the liquid of which the other passage
terminates, a single passage from above the seal to an evaporator,
a sump in said passage, and an evaporator to which said single
passage is connected above said sump.

4. In a refrigerating device, a generator-absorber, connections
therefrom through two passages, a liquid seal composed mainly of
the liquid absorbent used above which one of the passages
terminates, and within the liquid of which the other passage
terminates, a single passage from above the seal to an evaporator,
a sump in said passage, and an evaporator to which said single
passage is connected above said sump, said parts being arranged so
that all liquid will rain from the evaporator upon proper
positioning of the device.

5. In a refrigeration device, a generator-absorber, connections
therefrom through two passages, a liquid seal composed mainly of
the liquid absorbent used above which one of the passages
terminates, and within the liquid of which the other passage
terminates, a single passage from above the seal to an evaporator,
a sump in said passage, and an evaporator to which said single
passage is connected above said sump, said parts being arranged so
that all liquid will drain from the evaporator, upon proper
positioning of the device, and the passages to the
generator-absorber so arranged as to retain sufficient liquid to
restore the liquid seal when the device is in normal position.

6. In a refrigerating device, a generator- absorber, and a
freezing element connected thereto, including passageway forming
means for refrigerant during boiling off and reabsorption, and a
liquid seal composed mainly of the liquid absorbent used for one
of said passages at least, and means whereby the freezing element
can be drained into the generator absorber through said passages
with out destroying the liquid seal.

7. In a refrigerating device, a generator-absorber, and a
freezing element connected thereto, including passageway forming
means for refrigerant during boiling off and reabsorption, and a
liquid seal composed mainly of the liquid, absorbent used for one
of said passages at least, and means whereby the freezing element
can be drained into the generator-absorber through said passages
with out destroying the liquid seal, said structure having an
overflow sump connected thereto.

8. In a refrigeration unit, a generator-absorber casing, a
condenser-evaporator casing, tubular means connecting the same,
and extending beyond the condenser-evaporator to form a sump, and
a liquid container located within said tubular means and defining
influx and efflux passages from the generator-absorber between it
and the tubular means.

9. In a refrigeration unit, a generator-absorber casing, a
condenser-evaporator casing, tubular means connecting the same,
and extending beyond the condenser-evaporator to form a sump, and
means located within said tubular means and defining influx and
efflux passages from the generator-absorber, including a liquid
container.

10. In a refrigeration unit, a generator-absorber casing, a
condenser-evaporator casing, tubular means connecting the same,
and extending beyond the condenser-evaporator to form a sump, and
means located within said tubular means and defining influx and
efflux passages from the generator-absorber, including a liquid
container, said tubular means having a portion of its body
arranged to serve as a support for both casings upon an
intervening wall.

11. In a refrigerating unit a generator-absorber, and means
mounted upon said absorber and operated by heat, said means having
a sounding element arranged to give warning upon predetermined
temperatures of the generator-absorber, and comprising a retainer
for water having a steam bleed hole, and a discharge chamber of
which the generator-absorber forms a wall, a sounding device in
the wall of the discharge chamber, and a pressure operated
overflow from the retained to the discharge chamber.

12. In a generator-absorber, a casing therefor, a dome mounted
upon the top of said casing, and having a water receptacle there
in, spaced from the casing, and a portion of which the casing
forms a wall, having a sounding device therein, and steam pressure
operated means for discharging water from the receptacle to the
portion having the sounding device.

13. In a generator-absorber, a casing therefor, and heat
radiation fins upon the easing extending other than horizontally
and formed of inverted channels open at the top and bottom, for
the purpose described.

14. In a generator-absorber, a spherical shell therefor, and
heat radiation fins there on comprising inverted channel members
open at the top and bottom secured to the casing, and extending
other than parallel with the horizontal axis of the spherical
shell.

15. In combination wit a refrigerator cabinet, a refrigerating
unit having a generator-absorber-element, and a
condenser-evaporator element, means connecting them together, said
cabinet having an opening of sufficient size to receive the
condenser-evaporator, and a closure for said opening, and means
within the cabinet for engaging the condenser-evaporator, when
supported on the cabinet by the said connecting means.

16. In combination with a refrigerator cabinet, a refrigerating
unit having a generator-absorber element, and a
condenser-evaporator element, means connecting them together, said
cabinet having an opening of sufficient size to receive the
condenser-evaporator, and a closure for said opening, and means
within the cabinet for engaging the condenser-evaporator, when
supported on the cabinet by the said connecting means, said
cabinet having a groove therein in the wall thereof about said
closure for retaining the said connecting means.

17. In combination with a refrigerator cabinet, a refrigerating
unit having a generator-absorber element, a condenser evaporator
element, and means connecting them together, said
condenser-evaporator element including a tubular sump, said
cabinet having an opening of sufficient size to receive the
condenser evaporator element, a closure for said opening, and a
retainer located within the cabinet for engaging said tubular
sump, when the device is supported on the cabinet by said
connecting means.

18. In combination in, a refrigeration unit, a
generator-absorber of spherical shape, a condenser-evaporator
likewise of spherical shape, a tubular passage extending between
said absorber and evaporator devices, said tubular passage
containing all, connecting means between said devices, including a
vessel for entrapping liquid therein to form a cooling element
between said two devices for the flow of the refrigerant during
the generation step of its cycle of operations.

19. In combination in a refrigeration unit, a
generator-absorber of spherical shape, a condenser-evaporator
likewise of spherical shape, a tubular passage extending between
said absorber and evaporator devices, said tubular passage
containing all connecting means between said devices, including a
series of vessels containing liquid therein, for the purpose
described.

20. In combination in a refrigeration unit, a
generator-absorber comprising a container portion for absorbent,
an inlet therein in the form of a tube extending to a point below
the level of absorbent therein, tubular means extending from above
the level of absorbent in said container, a liquid seal applied
about the exit end of said tubular means, and means for preventing
a surge of the liquid of said seal through the said tubular means.

21. In combination in a refrigeration unit, a
generator-absorber comprising a container, a vessel for containing
liquid located adjacent thereto, a tube defining the level of
liquid in said vessel amid extending to a point below the level of
liquid in the container, and tubular means extending from above
the liquid level in said container to a point below the liquid in
said vessel, whereby a seal is provided.

22. In combination in a refrigeration unit, a
generator-absorber comprising a container, a vessel for containing
liquid located adjacent thereto, a tube defining the level of
liquid in said vessel and extending to a point below the level of
liquid in the container, and tubular means extending from above
the liquid level in said container to a point below the liquid in
said vessel, whereby a seal is provided, and a passageway from
above the level of liquid in said vessel to a condenser
evaporator.

23. In a refrigeration unit, a condenser-evaporator element
comprising a tubular passageway forming means, a liquid container
located in said passageway and requiring flow of gases around it,
a condenser shell connected to said tubular passageway means
beyond the liquid container, and a sump located below the point of
connection of the condenser shell.

24. In a refrigeration unit, a condenser-evaporator element
comprising a tubular passageway forming means, a liquid container
located in said passageway and requiring flow of gases around it,
a condenser shell connected to said tubular passageway means
beyond the liquid container, and a sump located below the point of
connection of the condenser shell, said condenser shell having a
closed tube extending from it into said passageway means having
holes therein for passage of refrigerant gases.

25. In a refrigeration unit, the combination of a
generator-absorber having separate inflow and outflow passages,
the latter protected by a liquid seal composed mainly of the
liquid absorbent used, a condenser-evaporator, and means for
defining a drainage position of the unit, such that the liquid
seal will not be destroyed in draining the condenser-evaporator
back into the generator-absorber.

26. In a refrigeration unit, the combination of a
generator-absorber having separate inflow and outflow passages,
the latter protected by a liquid seal composed mainly of the
liquid absorbent used, a condenser-evaporator means for partially
cooling the gases flowing from the generator before they reach the
condenser-evaporator, baffling means for entrapping the mist of
absorbent medium condensed by said partial cooling, and a sump to
catch the entrapped particles, so that the refrigerating medium is
substantially free of contained absorbent, when it reaches the
condenser-evaporator.

27. In a refrigerating unit, the combination of a
generator-absorber, a condenser-evaporator and passageways between
them to provide separate paths for flow of gases in opposing
directions, with the passageway for the generated gases having a
seal, and the passageway for the gases to be absorbed ending in an
open topped tubular member spaced from and located closely below
the level of the absorbent liquid at the start of the absorption
so as to set up surface agitation thereof and entering the
absorber from above to avoid a static head of liquid in the
passageway.

28. In a refrigerator unit, the combination of a
generator-absorber, a condenser-evaporator, and passageways
between them to provide separate paths for flow of gases out of
and into the generator-absorber, the passageway into the
generator-absorber having an unrestricted annular opening near the
surface of the absorbent liquid at the start of absorption so as
to set up surface agitation thereof and entering the absorber from
above so as to avoid a static head of liquid in the passageway.

29. In a refrigeration unit, a generator-absorber having a
sealed outlet therefrom, and an inlet thereunto, the latter being
arranged to carry the gases to be absorbed, said inlet formed as a
pipe which terminates in a spaced tubular member, open at the top,
and forming an unrestricted opening near the surface of the
absorbent at the period when absorption begins and enters the
absorber from above so as to avoid a static head of liquid in the
passageway.

30. In a refrigeration apparatus, a generator-absorber formed
in the shape of a sphere, thereby providing the strongest shape
for the required solid content thereof, said sphere provided
externally with heat radiating fins, thereby compensating for the
restricted surface of the spherical body proportionate to its
solid contents.

31. In an absorption system refrigerating device, a
generator-absorber shell having an outlet passage for products of
evaporation and a casing located on and in direct contact with the
generator-absorber shell adjacent the outlet passage adapted to
retain a body of cooling liquid in place whereby an initial
dehydration occurs at said outlet passage.

32. In combination with a vessel for containing cooling liquid,
a portable refrigeration unit comprising a generator-absorber
receptacle, and a condenser-evaporator receptacle, means extending
between said receptacle joining them together as a unit, and means
on said unit co-operating with the vessel for holding the
condenser-evaporator submerged in the liquid therein when the
condenser-evaporator, because of its empty condition would
otherwise float on the surface of said liquid.

33. In combination with a vessel for containing cooling liquid,
a portable refrigeration unit comprising a generator-absorber
receptacle, and a condenser-evaporator receptacle, means extending
between said receptacles joining them together as a unit, and
means in connection with the vessel for holding the
condenser-evaporator submerged in the liquid therein when the
condenser-evaporator, because of its empty condition would
otherwise float on the surface of said liquid, said means
comprising an element exterior of the vessel for holding the unit
in a vertical position, whereby the weight of the
generator-absorber holds down the condenser-evaporator.

34. In combination with a vessel for containing cooling liquid,
a portable refrigeration unit comprising a generator-absorber
receptacle, and a condenser-evaporator receptacle, means extending
between said receptacles joining them together as a unit, and
means in connection with the vessel for holding the
condenser-evaporator submerged in the liquid therein when the
condenser-evaporator, because of its empty condition would
otherwise float on the surface of said liquid, said means
comprising a bracket against which the generator-absorber
receptacle bears, thus preventing tipping of the device.

35. In combination with a vessel for containing cooling liquid,
a portable refrigeration unit comprising a generator-absorber
receptacle, and a condenser-evaporator receptacle, means extending
between said receptacles joining them together as a unit and means
in connection with the vessel for holding the condenser-evaporator
submerged in the liquid therein when the condenser-evaporator,
because of its empty condition would otherwise float on the
surface of said liquid, said means comprising a bracket against
which the generator-absorber receptacle bears, thus preventing
tipping of the device, and a member located on the joining means
between the receptacles which engages the edge of the said vessel.